CN114042638A

CN114042638A - Graphene chip processing and screening method

Info

Publication number: CN114042638A
Application number: CN202111373993.3A
Authority: CN
Inventors: 尧蚕
Original assignee: Guangzhou Minghan New Material Co ltd
Current assignee: Guangzhou Minghan New Material Co ltd
Priority date: 2021-11-18
Filing date: 2021-11-18
Publication date: 2022-02-15
Anticipated expiration: 2041-11-18
Also published as: CN114042638B

Abstract

The invention relates to the technical field of graphene chip processing, in particular to a graphene chip processing and screening method. The utility model provides a graphite alkene chip processing screening method, shell, first conveyer belt, first drive belt, first motor and second motor, the top bolt fastening of shell has the connection shell, and the rear side fixed mounting of connection shell has the extension board, and the internally mounted of extension board has first conveyer belt, and the right side of first conveyer belt is connected with steering gear, is connected for rotating between steering gear and the extension board, and steering gear's surface mounting has first drive belt, and the internally meshed on first drive belt right side installs the rotary drum. The invention has the beneficial effects that: this graphite alkene chip processing screening method improves on current basis, utilizes linkage structure on the device to carry out the screening, carries out automatic discharging and automatic feed, can also adjust the error allowed range of screening, has promoted the convenience and the controllability that the device used.

Description

Graphene chip processing and screening method

Technical Field

The invention relates to the technical field of graphene chip processing, in particular to a graphene chip processing and screening method.

Background

Graphene is a conductive material, has good electric conductivity and heat conductivity, and therefore the application range of graphene is very extensive, and the graphene chip is a product produced by utilizing the good electric conductivity of graphene, and the screening device for processing the graphene chip is required to be used in the production process of the graphene chip, and some problems still exist in the existing screening devices for the graphene chip when in use.

Current graphite alkene chip sieving mechanism is when using, is not convenient for carry out automatic classification to the graphite alkene chip of unidimensional not, can not carry out automatic discharging and pan feeding simultaneously at the in-process of screening moreover, can not carry out slow blanking in the detection, leads to graphite alkene chip to damage easily, and the security during the use is relatively poor, also can not adjust the precision that detects according to the error range that detects simultaneously, and application scope is lower.

Disclosure of Invention

The invention provides a graphene chip processing and screening method aiming at the technical problems in the prior art, and aims to solve the problems that the existing graphene chip screening device cannot slowly blank and discharge materials when in use, cannot adjust the detection precision according to the detection error range, and is low in application range.

The technical scheme for solving the technical problems is as follows: a graphene chip processing and screening method comprises the following steps:

A. conveying: conveying the materials by a feeding conveyer belt, and conveying the materials into the screening and detecting device;

B. screening: screening qualified products according to the size requirement, enabling the oversize graphene chip to stay on the upper layer, and taking off the unqualified products by workers for further processing;

C. adjusting detection precision: the error range of the screening size of the device is adjusted according to the error allowable range, so that different detection precision requirements are met;

D. discharging: after the detection precision is adjusted, the graphene chip is stably moved and pressed through a compression structure in the device, and qualified products automatically fall to a lower layer and are conveyed to the outside of the device through a discharge conveying belt to be collected by workers;

the screening detection device in the step a of the graphene chip processing and screening method includes:

the automatic feeding device comprises a shell, a first conveying belt, a first driving belt, a first motor and a second motor, wherein a connecting shell is fixed to the top of the shell through bolts, an extension plate is fixedly installed on the rear side of the connecting shell, the first conveying belt is installed inside the extension plate, a steering gear is connected to the right side of the first conveying belt, the steering gear is rotatably connected with the extension plate, the first driving belt is installed on the surface of the steering gear, a rotary drum is installed inside the right side of the first driving belt in a meshed mode, an inner disc is welded to the tail end of the rotary drum, and a circular disc is arranged on the outer side of the inner disc; a second motor is fixedly arranged inside the shell, an output shaft of the second motor is connected with the disc, connecting blocks are welded on the surface of the disc and are symmetrically distributed on the left side and the right side of the disc, the connecting blocks and the inner disc are connected in a welding mode, and a first motor is fixed on the surface of the inner disc through bolts; the inside of shell is fixed and is provided with built-in board, and the opening has been seted up to the front end of shell, and the inside fixed mounting of shell has the backup pad, and the side opening has all been seted up to the upper and lower both sides of shell side, and the middle fixed mounting of shell side has the side fishplate bar, and the third conveyer belt is installed to the bottom of shell side, and the inside left side fixed mounting of shell has built-in board.

The invention has the beneficial effects that:

1) the graphene chip processing and screening method is better in effect, the graphene chip processing and screening method is improved on the basis of the prior art, the linkage structure on the device is utilized to enable the device to drive the rotary drum to rotate in the size screening process, and meanwhile, the first conveying belt is driven to rotate through the steering gear and the first conveying belt on the device, so that the device can perform automatic feeding work during detection, the defect that the using modes of some screening devices are single is overcome, and the graphene chip processing and screening method has the advantage of higher practicability.

2) When the device is used, the transmission rod can be limited through the movable groove between the inner disc and the circular disc, so that the transmission rod moves along the track of the movable groove and the hollow part of the connecting frame to drive the folded plate to move intermittently left and right slowly, the left and right movement of the folded plate is matched with the feeding conveyer belt to carry out automatic detection work, the use convenience of the device is improved, meanwhile, the connecting frame can be driven to move back and forth by the rotation of the first motor, and then adjust the interval between the connection frame of adjacent two places to adjust folding plate reciprocating motion's interval, guarantee the device can adjust the error allowed range when measuring size of a dimension or screening as required, solved some current sieving mechanism and used not convenient defect, the functional relatively poor defect has the controllability stronger, the wider advantage of application scope.

3) This graphite alkene chip processing screening method effect is better, and the device drives the baffle and removes about in folded plate reciprocating motion to carrying out intermittent type nature for the inner shed who is used for the ejection of compact and opening or close, making the device can carry out automatic feed and ejection of compact when the screening, promoted the linkage effect of device, solved current sieving mechanism and consumed the defect that manpower and materials are more, had the better advantage of result of use.

On the basis of the technical scheme, the invention can be further improved as follows.

Furthermore, the rotating drum is connected with the shell in a bearing mode, the steering gear forms a rotating structure with the extending plate through a first transmission belt and the rotating drum, the inner disc and the circular disc are of an integrated structure; a second transmission belt is meshed and connected to an output shaft of the inner disc, the circle center of the inner disc and the circle center of the disc are located at the same point, a movable groove is formed between the disc and the inner disc, and a first screw rod is rotatably connected to the inner part of the inner disc; and a transmission rod is arranged in the movable groove.

The beneficial effect who adopts above-mentioned further scheme is that, carry on spacingly through the activity groove on the device to the transfer line to make the transfer line can remove along the activity groove, convenient follow-up removes the folded plate, promoted the convenience that the device used.

Furthermore, a first bevel gear is fixedly installed at the front end of the first screw rod, a third bevel gear is connected to the side surface of the first bevel gear in a meshed manner, a second bevel gear is installed at the front end of the third bevel gear in a meshed manner, a second screw rod is fixedly installed on the surface of the second bevel gear, and the second screw rod is in rotary connection with the inner disc; the outer side of the third bevel gear is connected with a second transmission belt in a meshed mode, and the right side of the second transmission belt is connected with an output shaft of the first motor; the outer side of the first screw rod is provided with a sliding block in a threaded manner, the surface of the sliding block is fixedly provided with connecting frames, and the connecting frames are symmetrically distributed on the front side and the rear side of the disc.

The beneficial effect who adopts above-mentioned further scheme is that, drive bevel gear synchronous rotation everywhere through the inside second drive belt of device to the drive screw rotates, makes the device can carry out synchronous control to the slider in the screw outside, and then makes two adjacent connection frames can remove in opposite directions or move dorsad.

Furthermore, the first bevel gear and the second bevel gear form a rotating structure with the inner disc through a third bevel gear; the thread directions of the surfaces of the first screw and the second screw are the same, the outer side bearing of the third bevel gear is provided with a connecting block, the left side and the right side of the connecting block are welded with fixing rods, the fixing rods are fixedly arranged on an inner disc, and the middle of the inner disc is provided with an inner groove; the front end of the transmission rod is in a hemisphere shape, the middle part of the transmission rod is provided with external threads, the middle threads of the transmission rod are provided with an adjusting nut, the outer side of the transmission rod is sleeved with a spring, the front end of the spring is fixedly provided with a folded plate, the transmission rod and the folded plate are in sliding connection, the tail end of the transmission rod is positioned in the through hole, the transmission rod and the shell form a sliding structure through the through hole, and the transmission rod and the folded plate form an elastic structure through the spring; the gliding spout of folded plate is offered to the inside of backup pad, and the internally mounted of folded plate has the second conveyer belt, and the right side protrusion of second conveyer belt is in the outside of folded plate, all fixed torsional spring, the terminal fixedly connected with elastic cord of torsional spring, on the roller of second conveyer belt and the side of shell.

Adopt above-mentioned further scheme's beneficial effect to be, guarantee through torsional spring and elastic cord and protect the in-process of the chip ejection of compact, security when having promoted the device and using, the transfer line can drive ejection of compact subassembly and remove simultaneously.

Further, an inner opening is formed in the surface of the inner plate, a pressing plate is fixedly arranged on the front side of the inner plate, a baffle is slidably mounted inside the inner plate, the baffle and the inner opening correspond to each other, an elastic rope is fixedly connected to the left side of the baffle, a guide wheel is arranged on the side face of the elastic rope, the guide wheel and the side connecting plate are rotatably connected, and the guide wheels are symmetrically distributed on the front side and the rear side of the side connecting plate; the baffle passes through the right side fixedly connected with slide bar that constitutes sliding structure baffle between elastic cord and folded plate and the built-in board, and the outside cover of slide bar is equipped with the pressure spring, and the head and the tail both ends of pressure spring are connected with slide bar and shell respectively, and the slide bar runs through in the inside of shell.

The beneficial effects of adopting above-mentioned further scheme are that, guarantee to reset the slide bar through the inside pressure spring of device, convenient follow-up uninterrupted detection achievement that carries on has promoted the practicality of device, and the device can drive discharge mechanism circulation rotation through bungee and leading wheel when using simultaneously, has promoted the result of use of device.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic top cross-sectional view of the present invention;

FIG. 3 is a schematic diagram of the structure at A in FIG. 2 according to the present invention;

FIG. 4 is a schematic diagram of the structure of FIG. 2 at B in accordance with the present invention;

FIG. 5 is a rear cross-sectional structural view of the drum of the present invention;

FIG. 6 is a schematic view of the connection structure of the inner disk and the third bevel gear of the present invention;

FIG. 7 is a schematic view of the connection structure of the transmission rod and the inner disk of the present invention;

FIG. 8 is a schematic view of a first drive belt and drum attachment configuration of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1. housing, 2, connecting shell, 3, extension plate, 4, first conveyor belt, 5, steering gear, 6, first transmission belt, 7, drum, 8, disk, 9, first motor, 10, second motor, 11, connecting block, 12, inner disk, 13, movable groove, 14, first screw, 15, first bevel gear, 16, third bevel gear, 17, second screw, 18, second bevel gear, 19, second conveyor belt, 20, inner groove, 21, connecting frame, 22, slider, 23, transmission rod, 24, through opening, 25, adjusting nut, 26, spring, 27, folding plate, 28, support plate, 29, sliding groove, 30, side joint plate, 31, third conveyor belt, 32, inner plate, 33, inner opening, 34, baffle, 35, bungee cord, 36, side opening, 37, guide wheel, 38, second conveyor belt, 39, torsion spring, 40, 39, 41, elastic band, 42, 41, elastic band, and the like, The device comprises a sliding rod 43, a pressure spring 44, a fixing rod 45 and a connecting block.

Detailed Description

The principles and features of this invention are described below in conjunction with the following drawings, which are set forth by way of illustration only and are not intended to limit the scope of the invention.

The application range of present graphite alkene chip is very extensive, nevertheless there are some weak points in present graphite alkene chip processing sieving mechanism still to graphite alkene chip processing production in-process, present graphite alkene chip sieving mechanism is when using, be not convenient for carry out automatic classification to the graphite alkene chip of not unidimensional, and can not carry out automatic discharging and pan feeding simultaneously at the in-process of screening, can not carry out slow blanking in the detection, lead to graphite alkene chip to damage easily, the security during the use is relatively poor, also can not adjust the precision of detection according to the error range that detects simultaneously, application scope is lower, to this inventor's proposition a graphite alkene chip processing screening method solves above-mentioned problem.

The present invention provides the following preferred embodiments

As shown in fig. 1 to 8, a graphene chip processing and screening method includes the following steps:

the screening detection device in the step A of the graphene chip processing and screening method comprises the following steps:

the device comprises an outer shell 1, a connecting shell 2, an extension plate 3, a first conveying belt 4, a steering gear 5, a first conveying belt 6, a rotary drum 7, a circular disc 8, a first motor 9, a second motor 10, a connecting block 11, an inner disc 12, a movable groove 13, a first screw 14, a first bevel gear 15, a third bevel gear 16, a second screw 17, a second bevel gear 18, a second conveying belt 19, an inner groove 20, a connecting frame 21, a sliding block 22, a transmission rod 23, a through hole 24, an adjusting nut 25, a spring 26, a folded plate 27, a supporting plate 28, a sliding groove 29, a side connecting plate 30, a third conveying belt 31, an inner plate 32, an inner opening 33, a baffle 34, a bungee cord 35, a side opening 36, a guide wheel 37, a second conveying belt 38, a torsion spring 39, an elastic band 40, a pressing plate 41, a sliding rod 42, a pressing spring 43, a fixing rod 44 and a block 45, wherein the connecting shell 2 is fixed on the top of the outer shell 1 through bolts, the extension plate 3 is fixed on the rear side of the connecting shell 2, a first conveying belt 4 is installed inside the extension plate 3, the right side of the first conveying belt 4 is connected with a steering gear 5, the steering gear 5 is rotatably connected with the extension plate 3, a first driving belt 6 is installed on the surface of the steering gear 5, a rotating drum 7 is installed inside the right side of the first driving belt 6 in a meshed mode, an inner disc 12 is welded to the tail end of the rotating drum 7, and a circular disc 8 is arranged on the outer side of the inner disc 12; a second motor 10 is fixedly arranged inside the shell 1, an output shaft of the second motor 10 is connected with the disc 8, connecting blocks 11 are welded on the surface of the disc 8, the connecting blocks 11 are symmetrically distributed on the left side and the right side of the disc 8, the connecting blocks 11 and the inner disc 12 are connected in a welding mode, and a first motor 9 is fixed on the surface of the inner disc 12 through bolts; the inside fixed interior board 32 that is provided with of shell 1, opening 24 has been seted up to the front end of shell 1, and the inside fixed mounting of shell 1 has backup pad 28, and side opening 36 has all been seted up to the upper and lower both sides of shell 1 side, and the middle fixed mounting of shell 1 side has side fishplate bar 30, and third conveyer belt 31 is installed to the bottom of shell 1 side, and the inside left side fixed mounting of shell 1 has interior board 32.

In the embodiment, as shown in fig. 1-2, in order to further improve the convenience of the device, the connection mode between the rotary drum 7 and the housing 1 is a bearing connection, the steering gear 5 forms a rotating structure with the extension plate 3 through the first transmission belt 6 and the rotary drum 7, the inner disc 12 and the circular disc 8 are of an integrated structure; a second transmission belt 19 is meshed and connected to an output shaft of the inner disc 12, the circle center of the inner disc 12 and the circle center of the disc 8 are on the same point, a movable groove 13 is arranged between the disc 8 and the inner disc 12, and a first screw 14 is rotatably connected to the inner part of the inner disc 12; the transmission rod 23 is arranged in the movable groove 13, and the transmission rod 23 is limited through the movable groove 13 on the device, so that the transmission rod 23 can move along the movable groove 13, and the folded plate 27 can be conveniently moved subsequently.

In the embodiment, as shown in fig. 1-2 and fig. 5-8, in order to further improve the adjustability of the device, a first bevel gear 15 is fixedly mounted at the front end of the first screw 14, a third bevel gear 16 is connected to the side surface of the first bevel gear 15 in a meshing manner, a second bevel gear 18 is mounted at the front end of the third bevel gear 16 in a meshing manner, a second screw 17 is fixedly mounted on the surface of the second bevel gear 18, and the second screw 17 is rotatably connected with the inner disc 12; the outer side of the third bevel gear 16 is engaged with a second transmission belt 19, and the right side of the second transmission belt 19 is connected with an output shaft of the first motor 9; a sliding block 22 is installed on the outer side of the first screw 14 in a threaded mode, a connecting frame 21 is fixedly arranged on the surface of the sliding block 22, and the connecting frame 21 is symmetrically distributed on the front side and the rear side of the disc 8; the second transmission belt 19 in the device drives the bevel gears to synchronously rotate, so that the screw rod is driven to rotate, the device can synchronously adjust the sliding blocks 22 on the outer sides of the screw rod, and the adjacent two connecting frames 21 can move oppositely or move back to back.

In this embodiment, as shown in fig. 1-3 and fig. 5-8, in order to further improve the linkage effect of the device, the first bevel gear 15 and the second bevel gear 18 both form a rotating structure with the inner disc 12 through the third bevel gear 16; the thread directions of the surfaces of the first screw 14 and the second screw 17 are the same, the outer side of the third bevel gear 16 is provided with a connecting block 45 in a bearing mode, fixing rods 44 are welded on the left side and the right side of the connecting block 45, the fixing rods 44 are fixedly arranged on the inner disc 12, and the middle of the inner disc 12 is provided with an inner groove 20; the front end of the transmission rod 23 is hemispherical, the middle part of the transmission rod 23 is provided with an external thread, the middle thread of the transmission rod 23 is provided with an adjusting nut 25, the outer side of the transmission rod 23 is sleeved with a spring 26, the front end of the spring 26 is fixedly provided with a folded plate 27, the transmission rod 23 and the folded plate 27 are in sliding connection, the tail end of the transmission rod 23 is positioned in the through hole 24, the transmission rod 23 forms a sliding structure with the shell 1 through the through hole 24, and the transmission rod 23 forms an elastic structure with the folded plate 27 through the spring 26; a sliding chute 29 for sliding the folded plate 27 is formed in the supporting plate 28, a second conveying belt 38 is installed in the folded plate 27, the right side of the second conveying belt 38 protrudes out of the folded plate 27, torsion springs 39 are fixedly arranged on a roller shaft of the second conveying belt 38 and the side surface of the shell 1, and elastic bands 40 are fixedly connected to the tail ends of the torsion springs 39; the protection in the chip discharging process is guaranteed through the torsion spring 39 and the elastic band 40, the safety of the device in use is improved, and meanwhile the transmission rod 23 can drive the discharging assembly to move.

In this embodiment, as shown in fig. 1 to 4, in order to further improve the using effect of the device, an inner opening 33 is formed on the surface of the inner board 32, a pressing board 41 is fixedly arranged on the front side of the inner board 32, a baffle 34 is slidably arranged inside the inner board 32, the baffle 34 and the inner opening 33 correspond to each other, an elastic rope 35 is fixedly connected to the left side of the baffle 34, a guide wheel 37 is arranged on the side surface of the elastic rope 35, the guide wheel 37 and the side connecting plate 30 are connected in a rotating manner, and the guide wheels 37 are symmetrically distributed on the front side and the rear side of the side connecting plate 30; the baffle 34 is fixedly connected with a sliding rod 42 through the right side of the baffle 34 which forms a sliding structure between the elastic band 40 and the folded plate 27 and the built-in plate 32, a pressure spring 43 is sleeved outside the sliding rod 42, the head end and the tail end of the pressure spring 43 are respectively connected with the sliding rod 42 and the shell 1, and the sliding rod 42 penetrates through the shell 1; the slide bar 42 is guaranteed to reset through the pressure spring 43 in the device, so that subsequent uninterrupted detection work is facilitated, the practicability of the device is improved, and meanwhile, the device can drive the discharging mechanism to rotate circularly through the elastic rope 35 and the guide wheel 37 when in use.

The specific working process of the invention is as follows:

(1) adjusting the allowable range of screening errors

The second driving belt 19 is driven by the first motor 9 to rotate, the third bevel gear 16 can be driven by the rotation of the second driving belt 19 to rotate, the second bevel gear 18 and the first bevel gear 15 are driven by the third bevel gear 16 to rotate, the first screw 14 and the second screw 17 can be driven to rotate when the first bevel gear 15 and the second bevel gear 18 rotate, the connecting frame 21 and the adjacent connecting frame 21 can move towards or away from each other under the limiting action of the inner groove 20 on the sliding block 22, the transmission rod 23 is limited by the movable groove 13 and the hollow part inside the connecting frame 21, in the adjusting process, the length of the transmission rod 23 passing through the linear groove inside the connecting frame 21 changes, the adjusting work is completed, the hemispherical body at the front end of the transmission rod 23 can ensure that the transmission rod 23 can move into the movable groove 13 at the hollow part inside the connecting frame 21 or move into the linear groove inside the connecting frame 21 from the movable groove 13, the spring 26 is compressed in the moving process, the adjusting nut 25 can be screwed in or out as required, so that the elastic force of the transmission rod 23 is adjusted, and the transmission rod 23 can be automatically switched back and forth between the hollow part inside the connecting frame 21 and the movable groove 13 by matching with the hemisphere at the front end of the transmission rod 23, so that the stable use of the device is ensured.

(2) Feeding while screening

Drive disc 8 and inner disc 12 through the inside second motor 10 of shell 1 and rotate, it slides in the groove to drive transfer line 23, when transfer line 23 passes through the inside sharp groove of connecting frame 21, can stimulate folded plate 27 and remove about slowly, the inside spout 29 of backup pad 28 guarantees that folded plate 27 can straight slide, compress tightly the chip through folded plate 27, thereby measure the size of chip, carry out the ejection of compact through interior opening 33, when disc 8 and inner disc 12 rotate, can be through steering gear 5, first drive belt 6 and rotary drum 7 drive first conveyer belt 4 and rotate, thereby make the device can carry out automatic feeding in the screening, the great chip of size can stop and supply the staff to take away on built-in board 32.

(3) Discharging

The flap 34 in the inner opening 33 can be moved by the movement of the flap 27, which, when the flap 27 is moved, pulls the second conveyor belt 38 by means of the torsion spring 39 and the elastic band 40, thereby, the second conveyor belt 38 is rotated, the chip is pressed on the pressing plate 41 by the rotation of the second conveyor belt 38, the load and the protection effect can be ensured by the elasticity of the torsion spring 39, the chip is prevented from being crushed, the flap 34 is moved leftwards during the movement of the flap 27 to the right, the flap 34 and the flap 27 are connected by a bungee cord 35 and a guide wheel 37, while the baffle 34 is opened, the sliding rod 42 moves leftwards, the compression spring 43 is compressed, the compression spring 43 enables the baffle 34 to automatically reset when the folding plate 27 moves leftwards, and finally, the chips fall onto the third conveying belt 31 for collection by workers, reach the effect of automatic feed and automatic discharging when screening through above-mentioned step, detachable connects shell 2 to be used for overhauing and clearing up the inside of shell 1.

In summary, the following steps: the automatic feeding device has the beneficial effects that the device is improved on the basis of the prior art, the linkage structure on the device is utilized to drive the rotary drum 7 to rotate in the process of screening the size, and the steering gear 5 and the first transmission belt 6 on the device are used for driving the first transmission belt 4 to rotate, so that the device can perform automatic feeding work during detection, the defect that the use modes of some screening devices in the prior art are single is overcome, and the automatic feeding device has the advantage of higher practicability;

in the using process of the device, the transmission rod 23 can be limited through the movable groove 13 between the inner disc 12 and the disc 8, so that the transmission rod 23 moves along the movable groove 13 and the track of the hollow part of the connecting frame 21 to drive the folding plate 27 to move intermittently in the left and right directions slowly, automatic detection work is carried out by matching the left and right movement of the folding plate 27 with the feeding conveyer belt, the using convenience of the device is improved, meanwhile, the connecting frame 21 can be driven to move back and forth through the rotation of the first motor 9, the distance between two adjacent connecting frames 21 can be adjusted, the reciprocating movement distance of the folding plate 27 can be adjusted, the device can be ensured to adjust the measured size or the error allowable range in screening according to requirements, the defect that some existing screening devices are inconvenient to use is overcome, the device has the defect of poor functionality and stronger adjustability, the application range is wider;

this graphite alkene chip processing screening method effect is better, and the device drives the baffle 34 and removes about folded plate 27 reciprocating motion to give and carry out intermittent type nature to the inner shed 33 that is used for the ejection of compact and open or close, make the device can carry out automatic feed and ejection of compact when the screening, promoted the linkage effect of device, solved current sieving mechanism and consumed the more defect of manpower and materials, had the better advantage of result of use.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. A graphene chip processing and screening method is characterized by comprising the following steps:

the conveying device comprises a shell (1), a first conveying belt (4), a first conveying belt (6), a first motor (9) and a second motor (10), wherein a connecting shell (2) is fixed to the top of the shell (1) through bolts, an extending plate (3) is fixedly installed on the rear side of the connecting shell (2), the first conveying belt (4) is installed inside the extending plate (3), a steering gear (5) is connected to the right side of the first conveying belt (4), the steering gear (5) is rotatably connected with the extending plate (3), the first conveying belt (6) is installed on the surface of the steering gear (5), a rotating drum (7) is installed on the inner portion of the right side of the first conveying belt (6) in a meshed mode, an inner disc (12) is welded to the tail end of the rotating drum (7), and a circular disc (8) is arranged on the outer side of the inner disc (12); a second motor (10) is fixedly arranged inside the shell (1), an output shaft of the second motor (10) is connected with the disc (8), connecting blocks (11) are welded on the surface of the disc (8), the connecting blocks (11) are symmetrically distributed on the left side and the right side of the disc (8), the connecting blocks (11) and the inner disc (12) are connected in a welding mode, and a first motor (9) is fixed on the surface of the inner disc (12) through bolts; the inside fixed built-in board (32) that is provided with of shell (1), opening (24) have been seted up to the front end of shell (1), and the inside fixed mounting of shell (1) has backup pad (28), and side opening (36) have all been seted up to the upper and lower both sides of shell (1) side, and the middle fixed mounting of shell (1) side has side joint board (30), and third conveyer belt (31) are installed to the bottom of shell (1) side, and the inside left side fixed mounting of shell (1) has built-in board (32).

2. The graphene chip processing and screening method according to claim 1, wherein the connection mode between the rotating drum (7) and the housing (1) is bearing connection, the steering gear (5) forms a rotating structure with the extension plate (3) through the first transmission belt (6) and the space between the rotating drum (7), and the rotating drum (7), the inner disc (12) and the circular disc (8) are of an integrated structure.

3. The graphene chip processing and screening method according to claim 2, wherein a second transmission belt (19) is connected to an output shaft of the inner disc (12) in a meshed manner, the center of the inner disc (12) and the center of the circular disc (8) are located at the same point, a movable groove (13) is formed between the circular disc (8) and the inner disc (12), and a first screw (14) is rotatably connected to the inner part of the inner disc (12); a transmission rod (23) is arranged in the movable groove (13).

4. The graphene chip processing and screening method according to claim 3, wherein a first bevel gear (15) is fixedly mounted at the front end of the first screw (14), a third bevel gear (16) is connected to the side surface of the first bevel gear (15) in a meshed manner, a second bevel gear (18) is mounted at the front end of the third bevel gear (16) in a meshed manner, a second screw (17) is fixedly mounted on the surface of the second bevel gear (18), and the second screw (17) is rotatably connected with the inner disc (12); the outer side of the third bevel gear (16) is engaged with a second transmission belt (19), and the right side of the second transmission belt (19) is connected with an output shaft of the first motor (9).

5. The graphene chip processing and screening method according to claim 4, wherein a slider (22) is installed on the outer side of the first screw (14) in a threaded manner, a connecting frame (21) is fixedly arranged on the surface of the slider (22), and the connecting frames (21) are symmetrically distributed on the front side and the rear side of the disc (8).

6. The graphene chip processing and screening method according to claim 5, wherein the first bevel gear (15) and the second bevel gear (18) both form a rotating structure with the inner disc (12) through a third bevel gear (16); the screw thread direction of the surfaces of the first screw rod (14) and the second screw rod (17) is the same, the outer side bearing of the third bevel gear (16) is provided with a connecting block (45), fixing rods (44) are welded on the left side and the right side of the connecting block (45), the fixing rods (44) are fixedly arranged on the inner disc (12), and an inner groove (20) is formed in the middle of the inner disc (12).

7. The graphene chip processing and screening method according to claim 1, wherein the front end of the transmission rod (23) is hemispheroidal, the middle part of the transmission rod (23) is provided with external threads, the middle threads of the transmission rod (23) are provided with an adjusting nut (25), the outer side of the transmission rod (23) is sleeved with a spring (26), the front end of the spring (26) is fixedly provided with a folded plate (27), the transmission rod (23) and the folded plate (27) are in sliding connection, the tail end of the transmission rod (23) is located inside the through hole (24), the transmission rod (23) forms a sliding structure with the shell (1) through the through hole (24), and the transmission rod (23) forms an elastic structure with the folded plate (27) through the spring (26); a sliding chute (29) for sliding a folded plate (27) is formed in the supporting plate (28), a second conveying belt (38) is arranged in the folded plate (27), the right side of the second conveying belt (38) protrudes out of the outer side of the folded plate (27), a torsion spring (39) is fixedly arranged on a roller shaft of the second conveying belt (38) and the side face of the shell (1), and an elastic band (40) is fixedly connected to the tail end of the torsion spring (39).

8. The graphene chip processing and screening method according to claim 7, wherein an inner opening (33) is formed in the surface of the built-in plate (32), a pressing plate (41) is fixedly arranged on the front side of the built-in plate (32), a baffle (34) is slidably mounted inside the built-in plate (32), the baffle (34) and the inner opening (33) correspond to each other, an elastic rope (35) is fixedly connected to the left side of the baffle (34), a guide wheel (37) is arranged on the side surface of the elastic rope (35), the guide wheel (37) and the side connection plate (30) are connected in a rotating mode, and the guide wheels (37) are symmetrically distributed on the front side and the rear side of the side connection plate (30).

9. The graphene chip processing and screening method according to claim 8, wherein a slide rod (42) is fixedly connected to the right side of the baffle (34) which forms a sliding structure through the elastic band (40) and the folded plate (27) and the built-in plate (32), a compression spring (43) is sleeved on the outer side of the slide rod (42), the head end and the tail end of the compression spring (43) are respectively connected with the slide rod (42) and the shell (1), and the slide rod (42) penetrates through the shell (1).